Node and method for managing a packet data network connection

ABSTRACT

Example embodiments presented herein are directed towards a Serving Gateway, a core network node and a Policy Control and Charging Rules Function, as well as corresponding methods therein, for managing a Packet Data Network connection of a wireless device.

TECHNICAL FIELD

Example embodiments presented herein are directed towards a ServingGateway, a core network node and a Policy Control and Charging RulesFunction, as well as corresponding methods therein, for managing aPacket Data Network connection of a wireless device.

BACKGROUND

In a typical cellular system, also referred to as a wirelesscommunications network, wireless terminals, also known as mobilestations and/or user equipment units communicate via a Radio AccessNetwork (RAN) to one or more core networks. The wireless terminals canbe Machine-to-Machine (M2M) devices, Internet-of-Things devices, mobilestations or user equipment units such as mobile telephones also known as“cellular” telephones, and laptops with wireless capability, forexample, portable, pocket, hand-held, computer-comprised, or car-mountedmobile devices which communicate voice and/or data with radio accessnetwork.

The radio access network covers a geographical area which is dividedinto cell areas, with each cell area being served by a base station,e.g., a Radio Base Station (RBS), which in some networks is also called“NodeB” or “B node” or “Evolved NodeB” or “eNodeB” or “eNB” and which inthis document also is referred to as a base station. A cell is ageographical area where radio coverage is provided by the radio basestation equipment at a base station site. Each cell is identified by anidentity within the local radio area, which is broadcast in the cell.The base stations communicate over the air interface operating on radiofrequencies with the user equipment units within range of the basestations.

In some versions of the radio access network, several base stations aretypically connected, e.g., by landlines or microwave, to a Radio NetworkController (RNC). The radio network controller, also sometimes termed aBase Station Controller (BSC), supervises and coordinates variousactivities of the plural base stations connected thereto. The radionetwork controllers are typically connected to one or more corenetworks.

The Universal Mobile Telecommunications System (UMTS) is a thirdgeneration mobile communication system, which evolved from the GlobalSystem for Mobile Communications (GSM), and is intended to provideimproved mobile communication services based on Wideband Code DivisionMultiple Access (WCDMA) access technology. UMTS Terrestrial Radio AccessNetwork (UTRAN) is essentially a radio access network using widebandcode division multiple access for user equipment units (UEs). The ThirdGeneration Partnership Project (3GPP) has undertaken to evolve furtherthe UTRAN and GSM based radio access network technologies. Long TermEvolution (LTE) together with Evolved Packet Core (EPC) is the newestaddition to the 3GPP family.

SUMMARY

During the operation of the wireless communications network, there maybe instances in which core network nodes fail or need to be restarted.Different procedures are in place to keep communication disturbances toa minimum during such failures or restarting of core network nodes. Anexample of such a procedure is a Network Triggered Service Restorationprocedure as specified in 3GPP TS 23.007, chapter 25. In such aprocedure, a node referred to as a Serving Gateway (SGW) detects thatmobility management node, for example, a Mobility Management Entity(MME) or a Serving General packet radio service Support Node (SGSN), hasfailed, the SGW will be required to keep the PDN connection. Later on,the SGW will issue a Downlink Data Notification with the IMSI of thewireless device associated with the PDN connection when it receives anydownlink data for the wireless device.

However, with recently developed new mechanism, especially for machinetype of wireless device, where wireless device may use extended DRX orenter Power Saving Mode, which isn't able to listen the paging request,in such case, paging triggered at receiving Downlink Data makes no senseat all, it just generates extra signaling over the network. Suchwireless device often uses those delay tolerant service, i.e. theservice can be delayed until the wireless device is reachable by thenetwork. However, it doesn't preclude the possibility to use a non-delaytolerant service.

Furthermore, there currently does not exist a means of providing dynamicor updated information regarding possible to change the attribute if aPDN connection is delay tolerance which is depending on what kind ofservices the wireless device is authorized to use.

In addition, there currently does not exist any specification that howsuch delay tolerant attribute of a PDN connection can affect themanagement of a PDN connection in the presence of a mobility managementnode failure or restart.

Thus, at least one object of the example embodiments presented herein ishow to effectively provide a mechanism when Network Triggered ServiceRestoration procedure is deployed in a communications network in which awireless device may be in an extended DRX or Power Saving Mode. Inparticular, an object of the example embodiments presented herein is howto manage a PDN connection for a wireless device with a network deployedwith the Network Triggered Service Restoration Procedure in the presenceof a mobility management node failure or restart.

At least one example advantage of the embodiments presented herein isthat unnecessary signaling is reduced. Based on an ability of a PDNconnection, associated with the wireless device, to receive delayedcommunications, the PDN connection may or may not be maintained in thepresence of a mobility management node failure or restart. Furthermore,another example advantage is that changes in delay tolerance, forexample, due to service or application usage, may be taken into accountwith respect to the management of the PDN connection.

Accordingly, some of the example embodiments are directed towards amethod, in a SGW for managing a PDN connection for a wireless device.The SGW is configured to support the Network Triggered ServiceRestoration Procedure. The method comprises receiving, from at least oneGTP, entity, a Delay Tolerance Connection Indicator (DTCI) indicating ifcommunications on an identified PDN connection towards the wirelessdevice can be delayed. The method further comprises storing the DTCIwithin the SGW. The method also comprises, upon detection of a failure(with restart or without restart) of a mobility management node servingthe wireless device, managing the PDN connection. The managing comprisesdeleting the PDN connection if the DTCI indicates the PDN connection isdelay tolerant. Or, the managing further comprises maintaining the PDNconnection if the DTCI indicates the PDN connection is not delaytolerant.

Some of the example embodiments are directed towards a SGW for managinga PDN connection for a wireless device. The SGW is configured to supporta Network Triggered Service Restoration Procedure. The SGW comprises aprocessor and a memory. The memory comprises instructions executable bythe processor whereby the SGW is operative to receive, from at least oneGTP, entity, a DTCI indicating if communications on an identified PDNconnection towards the wireless device can delayed. The SGW is furtheroperative to store the DTCI within the SGW. The SGW is also operativeto, upon detection of a failure (with restart or without restart) of amobility management node serving the wireless device, manage the PDNconnection. Within the management of the PDN connection, the SGW isoperative to delete the PDN connection if the DTCI indicates the PDNconnection is delay tolerant. Alternatively, the SGW is operative tomaintain the PDN connection if the DTCI indicates the PDN connection isnot delay tolerant.

Some of the example embodiments are directed towards a method, in a corenetwork node, for dynamically managing a PDN connection for a wirelessdevice. The core network node comprises a stored DTCI indicating ifcommunications on an identified PDN connection for the wireless devicecan be delayed. The method comprises receiving, from a PCRF or anothercore network node, an updated DTCI indicating a changed status withrespect to if the identified PDN connection for the wireless device isdelay tolerant. The method also comprises storing the updated DTCIwithin the core network node.

Some of the example embodiments are directed towards a core network nodefor dynamically managing a PDN connection for a wireless device. Thecore network node comprises a stored DTCI indicating if communicationson an identified PDN connection for the wireless device can be delayed.The core network node comprises a processor and a memory. The memorycomprises instructions executable by the processor whereby the corenetwork node is operative to receive, from a PCRF or another corenetwork node, an updated DTCI indicating a changed status with respectto if the identified PDN connection for the wireless device is delaytolerant. The core network node is further operative to store theupdated DTCI within the core network node.

Some of the example embodiments are directed towards a method, in aPCRF, for dynamically managing a PDN connection for a wireless device.The method comprises detecting a status change in a delay tolerance ofthe PDN connection. The status change presents a change with respect toif the identified PDN connection for the wireless device is capable ofreceiving delayed communications. The method further comprises updatinga DTCI based on the detected status change. The method further comprisessending, to a PGW, the updated DTCI.

Some of the example embodiments are directed towards a PCRF fordynamically managing a PDN connection for a wireless device. The PCRFcomprises a processor and a memory. The memory comprising instructionsexecutable by the processor whereby said PCRF is operative to detect astatus change in a delay tolerance of the PDN connection. The statuschange represents a change with respect to if the identified PDNconnection for the wireless device is capable of receiving delayedcommunications. The PCRF is further operative to update a DTCI based onthe detected status change. The PCRF is also operative to send, to a PDNGateway, PGW, the updated DTCI.

ABBREVIATIONS 3GPP Third Generation Partnership Project AS ApplicationServer BSC Base Station Controller DRX Discontinuous Reception DTCIDelay Tolerance Connection Indicator E-UTRAN Evolved UniversalTerrestrial Radio Access Network

eNodeB Evolved NodeB

EPC Evolved Packet Core GERAN GSM/EDGE Radio Access Network GGSN GatewayGPRS Support Node GPRS General Packet Radio Service GTP GPRS TunnelingProtocol GSM Global System for Mobile Communications HSS Home SubscriberServer IMSI International Mobile Subscriber Identity IoT Internet ofThings LTE Long Term Evolution M2M Machine-to-Machine MME MobilityManagement Entity PCRF Policy Control and Charging Rules Function PDNPacket Data Network PGW PDN Gateway RAN Radio Access Network RAU RoutingArea Update RBS Radio Base Station RNC Radio Network Controller RRCRadio Resource Control SGSN Serving GPRS Support Node SGW ServingGateway TAU Tracking Area Update UE User Equipment UMTS Universal MobileTelecommunications System UTRAN UMTS Terrestrial Radio Access NetworkWCDMA Wideband Code Division Multiple Access

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing will be apparent from the following more particulardescription of the example embodiments, as illustrated in theaccompanying drawings in which like reference characters refer to thesame parts throughout the different views. The drawings are notnecessarily to scale; emphasis instead being placed upon illustratingthe example embodiments.

FIG. 1 is an illustrative example of a wireless network;

FIG. 2 is message passing diagram depicting the management of a PDNconnection during a mobility procedure featuring a SGW relocation,according to some of the example embodiments presented herein;

FIG. 3 is message passing diagram depicting the management of a PDNconnection featuring a dynamic updating of a DTCI, according to some ofthe example embodiments presented herein;

FIG. 4 is an example node configuration of a SGW, core network node anda PCRF, according to some of the example embodiments;

FIG. 5A is a flow diagram depicting example operations which may betaken by the SGW, according to some of the example embodiments;

FIG. 5B is a module diagram depicting modules which are configured toperform the operations of FIG. 5A, according to some of the exampleembodiments;

FIG. 6A is a flow diagram depicting example operations which may betaken by the core network node, according to some of the exampleembodiments;

FIG. 6B is a module diagram depicting modules which are configured toperform the operations of FIG. 6A, according to some of the exampleembodiments;

FIG. 7A is a flow diagram depicting example operations which may betaken by the PCRF, according to some of the example embodiments; and

FIG. 7B is a module diagram depicting modules which are configured toperform the operations of FIG. 7A, according to some of the exampleembodiments.

DETAILED DESCRIPTION

In the following description, for purposes of explanation and notlimitation, specific details are set forth, such as particularcomponents, elements, techniques, etc. in order to provide a thoroughunderstanding of the example embodiments. However, it will be apparentto one skilled in the art that the example embodiments may be practicedin other manners that depart from these specific details. In otherinstances, detailed descriptions of well-known methods and elements areomitted so as not to obscure the description of the example embodiments.The terminology used herein is for the purpose of describing the exampleembodiments and is not intended to limit the embodiments presentedherein. It should be appreciated that all of the example embodimentspresented herein may be applicable to a GERAN, UTRAN or E-UTRAN basedsystem. It should further be appreciated that the term wireless device,wireless terminal, M2M device, MTC device, IoT device and user equipmentmay be used interchangeably.

General Overview

The example embodiments presented herein are directed towards themanagement of a PDN connection within a communication network whichsupports a Network Triggered Service Restoration procedure. In order toprovide a better explanation of the example embodiments presentedherein, a problem will first be identified and discussed.

Communications Network Overview

FIG. 1 provides a general example of a communication network 100. Asshown in FIG. 1, a user equipment (UE) 101 may be in communication witha Universal Terrestrial Radio Access Network (UTRAN) 103, an EvolvedUTRAN (E-UTRAN) 104, or a GSM Edge Radio Access Network (GERAN) 102subsystem in order to access communication to an operator or applicationserver 105. In gaining access to SCS, AS or hosts 105, theUTRAN/E-UTRAN/GERAN subsystem 102-104 may be in communication with aGeneral Packet Radio Service (GPRS) subsystem 107 or an Evolved PacketCore (EPC) subsystem 109. It should also be appreciated that the networkmay further comprise a WiFi subsystem, although not illustrated in FIG.1.

The GPRS subsystem 107 may comprise a Serving GPRS Support Node (SGSN)also known as Gn/Gp-SGSN 111, which may be responsible for the deliveryof data packets to and from the mobile stations within an associatedgeographical service area. The SGSN 111 may also be responsible forpacket routing, transfer, mobility management and connectivitymanagement. The GPRS subsystem 107 may also include a Gateway GPRSSupport Node 113, which may be responsible for the interworking betweenthe GPRS subsystem 107 and the PDN 105.

The EPC subsystem 109 may comprise a Mobility Management Entity 115,which may be responsible for mobility management, connectivitymanagement, idle mode UE tracking, paging procedures, attachment andactivation procedures, and small data and message transfer towards theE-UTRAN 104. The EPC subsystem may also comprise a Serving Gateway (SGW)117, which may be responsible for the routing and forwarding of datapackets. The EPC subsystem may also include a Packet data networkGateway (PGW) 119, which may be responsible for providing connectivityfrom the user equipment 101 to one or more PDN(s) 105. Both the SGSN111, the S4-SGSN 110 and the MME 115 may be in communication with a HomeSubscriber Server (HSS) 121, which may provide device identificationinformation, an International Mobile Subscriber Identity (IMSI),subscription information, etc. It should be appreciated that the EPCsubsystem 109 may also comprise a S4-SGSN 110, thereby allowing theGERAN 102 or UTRAN 103 subsystems to be accessed when the GPRS 107 isreplaced by the EPC 109.

The network further comprises a Policy Control and Charging RulesFunction (PCRF) 120. The PCRF 120 encompasses policy control decisionand flow-based charging control functionalities.

Extended Idle Mode DRX

3GPP has concluded a new technical study partly—Machine-Type and othermobile data applications Communications enhancements, more precisely for“UE Power Consumption Optimizations (UEPCOP)” part, where extended DRXfor wireless device in idle mode and wireless device Power Saving Modeare introduced.

The wireless device and the network may negotiate over non-accessstratum signaling the use of extended idle mode DRX for reducing itspower consumption, while being available for mobile terminating dataand/or network originated procedures within a certain delay dependent onthe DRX cycle value.

Applications that want to use extended idle mode DRX need to considerspecific handling of mobile terminating services or data transfers, andin particular they need to consider the delay tolerance of mobileterminated data. A network side application may send mobile terminateddata, an SMS, or a device trigger, and needs to be aware that extendedidle mode DRX may be in place.

In order to negotiate the use of extended idle mode DRX, the wirelessdevice requests extended idle mode DRX parameters during attachprocedure and RAU/TAU procedure. The SGSN/MME may reject or accept thewireless device request for enabling extended idle mode DRX. In case theSGSN/MME accepts the extended idle mode DRX, the SGSN/MME based onoperator policies may also provide different values of the extended idlemode DRX parameters than what was requested by the UE. If the SGSN/MMEaccepts the use of extended idle mode DRX, the wireless device appliesextended idle mode DRX based on the received extended idle mode DRXparameters. If the wireless device does not receive extended idle modeDRX parameters in the relevant accept message because the SGSN/MMErejected its request or because the request was received by SGSN/MME notsupporting extended idle mode DRX, the wireless device shall apply itsregular discontinuous reception as defined in TS 23.060, chapter 8.2.3and TS 23.401, chapter 5.13.

If a wireless device requests via NAS both to enable PSM (requesting anactive time and possibly a periodic TAU timer) and extended idle modeDRX (with a specific extended I-DRX cycle value), it is up to theSGSN/MME to decide whether to:

1. Enable only PSM, i.e. not accept the request for extended idle modeDRX.

2. Enable only extended idle mode DRX, i.e. not accept the request foran active time.

3. Enable both PSM (i.e. provide an active time) and extended idle modeDRX (i.e. provide an extended idle mode DRX parameters).

The decision between the three above, and which active time, periodicTAU timer and/or extended idle mode DRX cycle value to provide to theUE, are implementation dependent, based on local configuration, andpossibly other information available in the SGSN/MME. The methodselected is then used until the next Attach or RAU/TAU procedure isinitiated, when a new decision may be made. If both extended I-DRX andPSM are enabled, the extended I-DRX cycle should be set in order to havemultiple paging occasions while the active timer is running.

In the specific case when the PSM active time provided by the wirelessdevice is greater than the extended idle mode DRX cycle value providedby the wireless device, the SGSN/MME may enable both PSM and extendedidle mode DRX. This allows a wireless device to minimize powerconsumption during the active time e.g. when the active time is slightlylonger than typical active time values for example in the order ofseveral minutes.

In case extended idle mode DRX is enabled, the network handles mobileterminated data using high latency communication feature, as per clause4.5.7, GTP-C retransmissions as described in TS 23.060 and TS 23.401,and applies techniques to handle mobile terminated SMS as per TS 23.272and location services as per TS 23.271.

Wireless Device Power Saving Mode

A wireless device may adopt the PSM for reducing its power consumption.That mode is similar to power-off, but the wireless device remainsregistered with the network and there is no need to re-attach orre-establish PDN connections. A wireless device in PSM is notimmediately reachable for mobile terminating services. A wireless deviceusing PSM is available for mobile terminating services during the timeit is in connected mode and for the period of an Active Time that isafter the connected mode. The connected mode is caused by a mobileoriginated event like data transfer or signalling, e.g. after a periodicTAU/RAU procedure. PSM is therefore intended for wireless devices thatare expecting only infrequent mobile originating and terminatingservices and that can accept a corresponding latency in the mobileterminating communication.

Overview of the Example Embodiments

During the operation of the wireless communications network, there maybe instances in which core network nodes fail or need to be restarted.Different procedures are in place to keep communication disturbances toa minimum during such failures or restarting of core network nodes. Anexample of such a procedure is a Network Triggered Service Restorationprocedure as specified in 3GPP TS 23.007, chapter 25. In such aprocedure, a node referred to as a Serving Gateway (SGW) detects thatmobility management node, for example, a Mobility Management Entity(MME) or a Serving General packet radio service Support Node (SGSN), hasfailed, the SGW will be required to keep the PDN connection. Later on,the SGW will issue a Downlink Data Notification with the IMSI of thewireless device associated with the PDN connection when it receives anydownlink data for the wireless device.

However, with recently developed new mechanism, especially for machinetype of wireless device, where wireless device may use extended DRX orenter Power Saving Mode, which isn't able to listen the paging request,in such case, paging triggered at receiving Downlink Data makes no senseat all, it just generates extra signaling over the network.

Furthermore, there currently does not exist a means of providing dynamicor updated information regarding possible to change the attribute if aPDN connection is delay tolerance which is depending on what kind ofservices the wireless device are authorized to use.

In addition, there currently does not exist any specification that howsuch delay tolerant attribute of a PDN connection can affect themanagement of a PDN connection in the presence of a mobility managementnode failure or restart.

Thus, at least one object of the example embodiments presented herein ishow to effectively provide a mechanism for the case when NetworkTriggered Service Restoration procedure is deployed in a communicationsnetwork in which a wireless device may be in an extended DRX or PowerSaving Mode. In particular, an object of the example embodimentspresented herein is how to manage a PDN connection for a wireless devicewithin a network configured to support the Network Triggered ServiceRestoration Procedure. At least one other object of the exampleembodiments is how to effectively manage a PDN connection in thepresence of a mobility management node failure or restart.

At least one example advantage of the embodiments presented herein isthat unnecessary signaling is reduced. Based on an ability of a PDNconnection, associated with the wireless device, to receive delayedcommunications, the PDN connection may or may not be maintained in thepresence of a mobility management node failure or restart. Furthermore,another example advantage is that changes in delay tolerance, forexample, due to service or application usage, may be taken into accountwith respect to the management of the PDN connection in view of amobility management node failure or restart.

A new indication called a “Delay Tolerant Connection” is introduced,this indication is used by the PGW to indicate the PDN connection isdelay tolerant, for example, the PGW supports receiving a rejectioncause from the MME/SGSN via the SGW indicating that the wireless deviceis temporarily not reachable due to power saving during a networkinitiated procedure and holding the network initiated procedure, untilthe PGW receives the subsequent Modify Bearer Request message with theUASI indicating that the wireless device is available for end to endsignalling, for this PDN connection. However, this delay tolerantconnection indication is not used by the SGW.

PDN Connection Management During a Mobility Procedure with a SGW Change

According to some of the example embodiments, the SGW should make use ofthis indication, so that when the SGW detects MME/SGSN failure (MME/SGSNrestart or failure without restart), the SGW shall not keep the PDNconnections which are labelled with Delay Tolerant Connection. Toachieve this, in addition, such information “the PDN connection islabelled with Delay Tolerant Connection” shall be transferred to the newSGW during a mobility procedure with SGW change, i.e. inter MME/SGSNTAU/RAU for UEs in the Idle mode and inter MME/SGSN handover procedurefor UEs in the active/connected mode.

Such information can be included in Create Session Request message fromthe (target) MME/SGSN when the new SGW is contacted, or Modify BearerResponse from the PGW (the message is the response from the PGW when thenew SGW updates itself to the PGW with the Modify Bearer Requestmessage.

FIG. 2 illustrates how the Delay Tolerant Connection Indication (DTCI)is transferred to the new SGW (SGW2 is the new SGW) during a mobilityprocedure with a SGW change.

The green bold text denotes the first alternative, using Contexttransfer procedure (Context Request/Response/Acknowledge) to transferDTCI from the old MME/SGSN to the new MME/SGSN, and new MME/SGSNincludes DTCI in the Create Session Request message to the new SGW.

The red bold text denotes the second alternative, using Modify BearerResponse, the PGW provides DTCI to the new SGW. In this option, itimplicitly allows DTCI may be changed, so that in the subsequentsignalling Create Session Response, the new SGW should forward DTCI tothe new MME/SGSN.

MME is just an example; it may be an S4-SGSN, an MME or a Gn/Gp SGSN asthe source (old) mobility management node; it may be an S4-SGSN or anMME as the target (new) mobility management node. PGW may be a PGW. Thewireless device (UE) may camped on either 2G/3G or LTE.

Dynamic Management of Delay Tolerant Connection Indication for a GivenPDN Connection

According to prior art methods, a delay tolerant is set per PDNconnection and only when the PDN connection is established, it can't bechanged when the PDN connection is active.

However, according to the example embodiments presented herein, itshould be allowed that a PDN connection may be labelled as DelayTolerant Connection at the PDN connection, but changed to non-delaytolerant in a later stage; or vice versa.

For example:

1. When a wireless device activates a PDN connection, the PCRF, may setthe PDN connection as delay tolerant connection, according to thecurrent available subscription, e.g. Access Point Name, however if thewireless device later on, activates a service which is not delaytolerant, e.g., via a web portal to subscribe for certain service whichis not delay tolerant or via contacting an application server toregister a service which is not delay tolerant;

2. When the wireless device activates a PDN connection, the PCRF, mayset the PDN connection as non-delay tolerant connection, while if thewireless device has expired its granted quota, or if the wirelessdevice's subscription is changed, e.g. modified by end user via a webportal (when the end user is going to sleep)

In summary, the setting of Delay Tolerant or not, is not dependent ifthe wireless device has been activate power saving mode or extended DRX,but it depends on the services that UE is using. So that PCRF should beable to change the setting of Delay

Tolerant Connection indication while the PDN connection remains active.

FIG. 3 illustrates that the Delay Tolerant Connection Indication isduring a PDN connection creation procedure, but later on, the PDNconnection is reset to a normal PDN connection using Update BearerRequest message. It is possible for the PGW to use Create/Delete BearerRequest if the updated PCRF decision requires such bearercreation/deletion. The red highlighted text denotes the change due tothis invention. According to some of the example embodiments, such achange may be based on an application or service change which thewireless device undergoes.

Example Node Configuration

FIG. 4 illustrates an example node configuration of a node. Any nodediscussed herein may have the configuration illustrated in FIG. 4.Examples of such nodes are a SGW 117, a core network node (e.g., a SGSN111, a S4-SGSN 110, a MME 115, or a PGW 119), and a PCRF 120. The nodemay provide PDN connection management in a communications network,according to the example embodiments described herein. The node maycomprise a receiver 401 that may be configured to receive communicationdata, instructions, delay tolerance information, wireless deviceapplication or service usage information, and/or messages. The node mayalso comprise a transmitter 402 that may be configured to transmitcommunication data, instructions, delay tolerance information, wirelessdevice application or service usage information, and/or messages. Itshould be appreciated that the receiver 401 and transmitter 402 may becomprised as any number of transceiving, receiving, and/or transmittingunits, modules or circuitry. It should further be appreciated that thereceiver 401 and transmitter 402 may be in the form of any input oroutput communications port known in the art. The receiver 401 andtransmitter 402 may comprise RF circuitry and baseband processingcircuitry (not shown).

The node may also comprise a processing unit or circuitry 403 which maybe configured to process information related to the management of a PDNconnection as described herein. The processing circuitry 403 may be anysuitable type of computation unit, for example, a microprocessor,digital signal processor (DSP), field programmable gate array (FPGA), orapplication specific integrated circuit (ASIC), or any other form ofcircuitry or module. The node may further comprise a memory unit orcircuitry 405 which may be any suitable type of computer readable memoryand may be of volatile and/or non-volatile type. The memory 405 may beconfigured to store received, transmitted, and/or measured data, deviceparameters, communication priorities, delay tolerance information,wireless device application or service usage information, and/orexecutable program instructions.

Example Node Operations

FIG. 5A is a flow diagram depicting example operations which may betaken by the SGW for managing a PDN connection for a wireless device asdescribed herein. It should also be appreciated that FIG. 5A comprisessome operations which are illustrated with a solid border and someoperations which are illustrated with a dashed border. The operationswhich are comprised in a solid border are operations which are comprisedin the broadest example embodiment. The operations which are comprisedin a dashed border are example embodiments which may be comprised in, ora part of, or are further operations which may be taken in addition tothe operations of the broader example embodiments. It should beappreciated that these operations need not be performed in order.Furthermore, it should be appreciated that not all of the operationsneed to be performed. The example operations may be performed in anyorder and in any combination. The example operations are furtherdescribed in at least the non-limiting summary of example embodiments.

It should be appreciated that the numbering featured in FIG. 5Acorrespond to the reference numerals described in the ‘Summary of theExample Embodiments’ section.

FIG. 5B is a module diagram depicting modules which may perform at leastsome of the operations of FIG. 5A.

FIG. 6A is a flow diagram depicting example operations which may betaken by the core network node for managing a PDN connection for awireless device as described herein. It should also be appreciated thatFIG. 6A comprises some operations which are illustrated with a solidborder and some operations which are illustrated with a dashed border.The operations which are comprised in a solid border are operationswhich are comprised in the broadest example embodiment. The operationswhich are comprised in a dashed border are example embodiments which maybe comprised in, or a part of, or are further operations which may betaken in addition to the operations of the broader example embodiments.It should be appreciated that these operations need not be performed inorder. Furthermore, it should be appreciated that not all of theoperations need to be performed. The example operations may be performedin any order and in any combination. The example operations are furtherdescribed in at least the non-limiting summary of example embodiments.

It should be appreciated that the numbering featured in FIG. 6Acorrespond to the reference numerals described in the ‘Summary of theExample Embodiments’ section.

FIG. 6B is a module diagram depicting modules which may perform at leastsome of the operations of FIG. 6A.

FIG. 7A is a flow diagram depicting example operations which may betaken by the PCRF for managing a PDN connection for a wireless device asdescribed herein. It should also be appreciated that FIG. 7A comprisessome operations which are illustrated with a solid border and someoperations which are illustrated with a dashed border. The operationswhich are comprised in a solid border are operations which are comprisedin the broadest example embodiment. The operations which are comprisedin a dashed border are example embodiments which may be comprised in, ora part of, or are further operations which may be taken in addition tothe operations of the broader example embodiments. It should beappreciated that these operations need not be performed in order.Furthermore, it should be appreciated that not all of the operationsneed to be performed. The example operations may be performed in anyorder and in any combination. The example operations are furtherdescribed in at least the non-limiting summary of example embodiments.

It should be appreciated that the numbering featured in FIG. 7Acorrespond to the reference numerals described in the ‘Summary of theExample Embodiments’ section.

FIG. 7B is a module diagram depicting modules which may perform at leastsome of the operations of FIG. 7A.

Some embodiments describe above may be summarized in the followingmanner:One embodiment is directed to a method in a SGW for managing a PDNconnection for a wireless device. The method comprises: receiving, fromat least one GTP entity, a DTCI indicating if communications on anidentified PDN connection towards the wireless device can be delayed;storing the DTCI within the SGW; and upon detection of a failure (withrestart or without restart) of a mobility management node serving thewireless device, managing the PDN connection, wherein the managingcomprises; deleting the PDN connection if the DTCI indicates the PDNconnection is delay tolerant; or maintaining the PDN connection if theDTCI indicates the PDN connection is not delay tolerant.It should be appreciated that not setting the DTCI may also be usedtogether with other features and other operator policies to determine ifthe PDN connection should be maintained. Examples of such features andoperator policies are QCI/ARP/APN and such parameters. The SGW maydetermine if the PDN connection should be kept based on the DTCI, whichmay include any number of parameters.According to such an example embodiment, the SGW will save the DTCI andmanage the PDN connection based on the saved DTCI value. In contrast toprior art methods, the SGW blindly forwards such a value to the mobilitymanagement node. In prior art methods, the SGW does not utilize theDTCI.In utilizing the DTCI, the SGW will, upon the detection of a failure(with a restart or without restart) of the mobility management node, maykeep the PDN connection if the DTCI value indicates the connection isnot delay tolerant. If the PDN connection is delay tolerant, the PDNconnection will be deleted, that is, the PDN connection is not eligiblefor the network triggered service restoration procedure. This is toavoid unnecessary paging signalling since the wireless device mayactivate a power saving mechanism, for example, extended DRX is enabled,or entering power saving state.The DTCI may be provided in the form of a flag, cause code or any otherform of indication known in the art.In the method, the at least one GTP entity may be a PGW, and thereceiving may further comprise receiving, from the PGW, the DTCI duringa PDN connection creation procedure.According to such example embodiments, the DTCI may be provided, forexample, during a PDN connection creation procedure in a Create SessionResponse message.In the method, wherein the receiving occurs during a mobility procedurewith a SGW relocation, the SGW may be a new SGW and the at least one GTPentity may be the new mobility management node which will serve thewireless device upon completion of the mobility procedure, the receivingfurther comprises receiving, from the new mobility management node, theDTCI during mobility procedure.According to such example embodiments, the DTCI may be provided, forexample, in a Context Response message. It should be appreciated thatthe new mobility management node receives the DTCI in a Context Responsemessage from the old mobility management node.In the method, wherein the receiving occurs during a mobility procedurewith a SGW relocation, the SGW may be a new SGW and the at least one GTPentity may be a PGW, the receiving further comprises receiving, from thePGW, the (e.g. the current) DTCI during mobility procedure.According to such example embodiments, the DTCI may be provided, forexample, in a Modify Bearer Response message from the PGW.The method may further comprise receiving a dynamically updated DTCIfrom the at least one GTP entity.It should be appreciated that the dynamically updated DTCI may beprovided in an Update/Create/Delete bearer request or a Modify BearerResponse message. According to some of the example embodiments, such adynamic update of the DTCI may be based on service or application usechanges employed by the wireless device. It should be appreciated thatsuch a dynamically updated DTCI may originate from the PCRF and beprovided to the SGW via the PGW.In the method, the mobility management node may be a MME, a SGSN, or aS4-SGSN.Some other embodiments describe above may be summarized in the followingmanner:One other embodiment is directed to a SGW for managing a PDN connectionfor a wireless device. The SGW comprising a processor and a memory, saidmemory comprising instructions executable by said processor whereby saidSGW is operative to: receive from at least one GTP entity a DTCIindicating if communications on an identified PDN connection towards thewireless device can be delayed; store the DTCI within the SGW; and upondetection of a failure (with restart or without restart) of a mobilitymanagement node serving the wireless device, manage the PDN connection,wherein the management comprises; delete the PDN connection if the DTCIindicates the PDN connection is delay tolerant; or maintain the PDNconnection if the DTCI indicates the PDN connection is not delaytolerant.It should be appreciated that not setting the DTCI may also be usedtogether with other features and other operator policies to determine ifthe PDN connection should be maintained. Examples of such features andoperator policies are QCI/ARP/APN and such parameters. The SGW maydetermine if the PDN connection should be kept based on the DTCI, whichmay include any number of parameters.According to such an example embodiment, the SGW will save the DTCI andmanage the PDN connection based on the saved DTCI value. In contrast toprior art methods, the SGW blindly forwards such a value to the mobilitymanagement node. In prior art methods, the SGW does not utilize theDTCI.In utilizing the DTCI, the SGW will, upon the detection of a failure(with a restart or without restart) of the mobility management node, maykeep the PDN connection if the DTCI value indicates the connection isnot delay tolerant. If the PDN connection is delay tolerant, the PDNconnection will be deleted, that is, the PDN connection is not eligiblefor the network triggered service restoration procedure. This is toavoid unnecessary paging signalling since the wireless device mayactivate a power saving mechanism, for example, extended DRX is enabled,or entering power saving state.The DTCI may be provided in the form of a flag, cause code or any otherform of indication known in the art.With respect to the SGW of this exemplifying embodiment, the at leastone GTP entity may be a PGW, and the SGW may be further operative toreceive, from the PGW, the DTCI during a PDN connection creationprocedure.According to such example embodiments, the DTCI may be provided, forexample, during a PDN connection creation procedure in a Create SessionResponse message.With respect to the SGW of this exemplifying embodiment, the SGW may beoperative to receive the DTCI during a mobility procedure with a SGWrelocation, the SGW may be a new SGW and the at least one GTP entity maybe the new mobility management which will serve the wireless device uponcompletion of the mobility procedure, the SGW may further be operativeto receive, from the new mobility management node, the DTCI duringmobility procedure.According to such example embodiments, the DTCI may be provided, forexample, in a Context Response message. It should be appreciated thatthe new mobility management node receives the DTCI in a Context Responsemessage from the old mobility management node.With respect to the SGW of this exemplifying embodiment, the SGW may beoperative to receive the DTCI during a mobility procedure with a SGWrelocation, the SGW may be a new SGW and the at least one GTP entity maybe a PGW, the SGW may further be operative to receive, from the PGW, the(e.g. the current) DTCI during mobility procedure.According to such example embodiments, the DTCI may be provided, forexample, in a Modify Bearer Response message from the PGW.With respect to the SGW of this exemplifying embodiment, the SGW may befurther operative to receive a dynamically updated DTCI from the atleast one GTP entityIt should be appreciated that the dynamically updated DTCI may beprovided in an Update/Create/Delete bearer request or a Modify BearerResponse message. According to some of the example embodiments, such adynamic update of the DTCI may be based on service or application usechanges employed by the wireless device. It should be appreciated thatsuch a dynamically updated DTCI may originate from the PCRF and beprovided to the SGW via the PGW.With respect to the SGW of this exemplifying embodiment, the mobilitymanagement node may be a Mobility Management Entity, a Serving Generalpacket radio service Support Node (SGSN), or a S4-SGSNSome other embodiments describe above may be summarized in the followingmanner:One other embodiment is directed to a method, in a core network node fordynamically managing a PDN, connection for a wireless device (101), thecore network node comprising a stored DTCI, indicating if communicationson an identified PDN connection for the wireless device can be delayed,the core network node being configured for a Network Triggered ServiceRestoration Procedure. The method comprises: receiving, from a PCRF, oranother core network node, an updated DTCI indicating a changed statuswith respect to if the identified PDN connection for the wireless deviceis delay tolerant; and storing the updated DTCI within the core networknode.According to such embodiments, the DTCI, as an attribute of a PDNconnection, is provided in a dynamic fashion. Thus, an updated DTCI isprovided when the PDN connection is active (i.e., not only during aninitial attach, or a PDN connection creation procedure or a mobilityprocedure).According to such example embodiments, the update to the DTCI is basedon an application or service being utilized by the identified PDNconnection for the wireless device. For example, a PDN connection whichwas previously identified as being delay tolerant according tosubscribed or authorized services and later on it is used for servicesin which a delay is not acceptable. Thus, an updated DTCI is sentindicating that the PDN connection is not delay tolerant.The DTCI may be provided in the form of a flag, cause code or any otherform of identification known in the art.In the method, the updated DTCI may be received from the PCRF and thecore network node may be a PGW, and the method may further comprise;forwarding, to a SGW, the updated DTCI.According to such example embodiments, the updated DTCI may be providedfrom the PCRF to the PGW in a Re-Authorization Request message.In the method, the updated DTCI may be received from a PGW, and the corenetwork node may be a SGW, and the method may further compriseforwarding, to a mobility management node, the updated DTCI.The method may further comprise managing the PDN connection, wherein themanaging comprises: deleting the PDN connection if the DTCI indicatesthe PDN connection is delay tolerant; or maintaining the PDN connectionif the DTCI indicates the PDN connection is not delay tolerant.According to such example embodiments, the updated DTCI may be providedfrom the PGW to the SGW in an Update/Create/Delete Bearer Requestmessage.In the method, the updated DTCI may be received from a SGW, and the corenetwork node may be a mobility management node.In the method, the mobility management node may be a Mobility ManagementEntity, a Serving General packet radio service Support Node (SGSN), or aS4-SGSN.Some other embodiments describe above may be summarized in the followingmanner:One other embodiment is directed to a core network node for dynamicallymanaging a PDN connection for a wireless device. The core network nodecomprises a stored DTCI indicating if communications on an identifiedPDN connection for the wireless device can be delayed. The core networknode comprises a processor and a memory, said memory comprisinginstructions executable by said processor whereby said core network nodeis operative to: receive, from a PCRF or another core network node, anupdated DTCI indicating a changed status with respect to if theidentified PDN connection for the wireless device is delay tolerant; andstore the updated DTCI within the core network node.According to such embodiments, the DTCI, as an attribute of a PDNconnection, is provided in a dynamic fashion. Thus, an updated DTCI isprovided when the PDN connection is active (i.e., not only during aninitial attach, or a PDN connection creation procedure or a mobilityprocedure).According to such example embodiments, the update to the DTCI is basedon an application or service being utilized by the identified PDNconnection for the wireless device. For example, a PDN connection whichwas previously identified as being delay tolerant according tosubscribed or authorized services and later on it is used for servicesin which a delay is not acceptable. Thus, an updated DTCI is sentindicating that the PDN connection is not delay tolerant.The DTCI may be provided in the form of a flag, cause code or any otherform of identification known in the art.With respect to the core network node of this exemplifying embodiment,the updated DTCI may be received from the PCRF and the core network nodemay be a PGW, the core network node may be further operative to forward,to a SGW, the updated DTCI.According to such example embodiments, the updated DTCI may be providedfrom the PCRF to the PGW in a Re-Authorization Request message.With respect to the core network node of this exemplifying embodiment,the updated DTCI may be received from a PGW, and the core network nodemay be a SGW, and the core network node may be further operative toforward, to a mobility management node, the updated DTCI.With respect to the core network node of this exemplifying embodiment,the management of the PDN connect may further comprise the core networknode being operative to: delete the PDN connection if the DTCI indicatesthe PDN connection is delay tolerant; or maintain the PDN connection ifthe DTCI indicates the PDN connection is not delay tolerant.According to such example embodiments, the updated DTCI may be providedfrom the PGW to the SGW in an Update/Create/Delete Bearer Requestmessage.With respect to the core network node of this exemplifying embodiment,the updated DTCI may be received from a SGW, and the core network nodemay be a mobility management node.With respect to the core network node of this exemplifying embodiment,the mobility management node may be a Mobility Management Entity (115),a Serving General packet radio service Support Node, SGSN (111), or aS4-SGSN (110).Some other embodiments describe above may be summarized in the followingmanner:One other embodiment is directed to a method, in PCRF for dynamicallymanaging a PDN connection for a wireless device. The method maycomprise: detecting a status change in a delay tolerance of the PDNconnection, wherein the status change presents a change with respect toif the identified PDN connection for the wireless device is capable ofreceiving delayed communications; updating a DTCI based on the detectedstatus change; and sending, to a PGW, the updated DTCI.Some other embodiments describe above may be summarized in the followingmanner:One other embodiment is directed to a PCRF for dynamically managing aPDN, connection for a wireless device. The PCRF may comprise a processorand a memory, said memory comprising instructions executable by saidprocessor whereby said PCRF is operative to: detect a status change in adelay tolerance of the PDN connection, wherein the status changepresents a change with respect to if the identified PDN connection forthe wireless device is capable of receiving delayed communications;update a DTCI, based on the detected status change; and send, to a PGW,the updated DTCI.

It should be noted that although terminology from 3GPP LTE has been usedherein to explain the example embodiments, this should not be seen aslimiting the scope of the example embodiments to only the aforementionedsystem. Other wireless systems, including WCDMA, WiMax, UMB, WiFi andGSM, may also benefit from the example embodiments disclosed herein.

The description of the example embodiments provided herein have beenpresented for purposes of illustration. The description is not intendedto be exhaustive or to limit example embodiments to the precise formdisclosed, and modifications and variations are possible in light of theabove teachings or may be acquired from practice of various alternativesto the provided embodiments. The examples discussed herein were chosenand described in order to explain the principles and the nature ofvarious example embodiments and its practical application to enable oneskilled in the art to utilize the example embodiments in various mannersand with various modifications as are suited to the particular usecontemplated. The features of the embodiments described herein may becombined in all possible combinations of methods, apparatus, modules,systems, and computer program products. It should be appreciated thatthe example embodiments presented herein may be practiced in anycombination with each other.

It should be noted that the word “comprising” does not necessarilyexclude the presence of other elements or steps than those listed andthe words “a” or “an” preceding an element do not exclude the presenceof a plurality of such elements. It should further be noted that anyreference signs do not limit the scope of the claims, that the exampleembodiments may be implemented at least in part by means of bothhardware and software, and that several “means”, “units” or “devices”may be represented by the same item of hardware.

Also note that terminology such as user equipment should be consideredas non-limiting. A device or user equipment as the term is used herein,is to be broadly interpreted to include a radiotelephone having abilityfor Internet/intranet access, web browser, organizer, calendar, a camera(e.g., video and/or still image camera), a sound recorder (e.g., amicrophone), and/or global positioning system (GPS) receiver; a personalcommunications system (PCS) user equipment that may combine a cellularradiotelephone with data processing; a personal digital assistant (PDA)that can include a radiotelephone or wireless communication system; alaptop; a camera (e.g., video and/or still image camera) havingcommunication ability; and any other computation or communication devicecapable of transceiving, such as a personal computer, a homeentertainment system, a television, etc. It should be appreciated thatthe term user equipment may also comprise any number of connecteddevices. Furthermore, it should be appreciated that the term ‘userequipment’ shall be interpreted as defining any device which may have aninternet or network access. Furthermore, it should be appreciated thatthe term M2M device shall be interpreted as a sub-class of userequipment which engage in infrequent communications.

The various example embodiments described herein are described in thegeneral context of method steps or processes, which may be implementedin one aspect by a computer program product, embodied in acomputer-readable medium, including computer-executable instructions,such as program code, executed by computers in networked environments. Acomputer-readable medium may include removable and non-removable storagedevices including, but not limited to, Read Only Memory (ROM), RandomAccess Memory (RAM), compact discs (CDs), digital versatile discs (DVD),etc. Generally, program modules may include routines, programs, objects,components, data structures, etc. that perform particular tasks orimplement particular abstract data types. Computer-executableinstructions, associated data structures, and program modules representexamples of program code for executing steps of the methods disclosedherein. The particular sequence of such executable instructions orassociated data structures represents examples of corresponding acts forimplementing the functions described in such steps or processes.

In the drawings and specification, there have been disclosed exemplaryembodiments. However, many variations and modifications can be made tothese embodiments. Accordingly, although specific terms are employed,they are used in a generic and descriptive sense only and not forpurposes of limitation, the scope of the embodiments being defined bythe following summary of example embodiments.

1. A method, in a Serving Gateway, SGW, for managing a Packet DataNetwork, PDN, connection for a wireless device, the method comprising:receiving, from at least one General packet radio service TunnelingProtocol, GTP, entity, a Delay Tolerance Connection Indicator, DTCI,indicating if communications on an identified PDN connection towards thewireless device can be delayed; storing the DTCI within the SGW; andupon detection of a failure of a mobility management node serving thewireless device, managing the PDN connection, wherein the managingcomprises: deleting the PDN connection if the DTCI indicates the PDNconnection is delay tolerant; or maintaining the PDN connection if theDTCI indicates the PDN connection is not delay tolerant.
 2. The methodof claim 1, wherein the at least one GTP entity is a PDN Gateway, PGW,and the receiving further comprises receiving, from the PGW, the DTCIduring a PDN connection creation procedure.
 3. The method of claim 1,wherein the receiving occurs during a mobility procedure with a SGWrelocation, the SGW is a new SGW and the at least one GTP entity is thenew mobility management node which will serve the wireless device uponcompletion of the mobility procedure, the receiving further comprisesreceiving, from the new mobility management node, the DTCI duringmobility procedure.
 4. The method of claim 1, wherein the receivingoccurs during a mobility procedure with a SGW relocation, the SGW is anew SGW and the at least one GTP entity is a PGW, the receiving furthercomprises receiving, from the PGW, the DTCI during mobility procedure.5. The method of claim 1, further comprising receiving a dynamicallyupdated DTCI from the at least one GTP entity.
 6. The method of claim 1,wherein the mobility management node is a Mobility Management Entity, aServing General packet radio service Support Node, SGSN, or a S4-SGSN.7. A Serving Gateway, SGW, for managing a Packet Data Network, PDN,connection for a wireless device, the SGW comprising a processor and amemory, said memory comprising instructions executable by said processorwhereby said SGW is operative to: receive, from at least one Generalpacket radio service Tunneling Protocol, GTP, entity, a Delay ToleranceConnection Indicator, DTCI, indicating if communications on anidentified PDN connection towards the wireless device can be delayed;store the DTCI within the SGW; and upon detection of a failure of amobility management node serving the wireless device, manage the PDNconnection, wherein the management comprises delete the PDN connectionif the DTCI indicates the PDN connection is delay tolerant; or maintainthe PDN connection if the DTCI indicates the PDN connection is not delaytolerant.
 8. The SGW of claim 7, wherein the at least one GTP entity isa PDN Gateway, PGW, the SGW is further operative to receive, from thePGW, the DTCI during a PDN connection creation procedure.
 9. The SGW ofclaim 7, wherein the SGW is operative to receive the DTCI during amobility procedure with a SGW relocation, the SGW is a new SGW and theat least one GTP entity is the new mobility management which will servethe wireless device upon completion of the mobility procedure, the SGWis further operative to receive, from the new mobility management node,the DTCI during mobility procedure.
 10. The SGW of claim 7, wherein theSGW is operative to receive the DTCI during a mobility procedure with aSGW relocation, the SGW is a new SGW and the at least one GTP entity isa PGW, the SGW is further operative to receive, from the PGW, the DTCIduring mobility procedure.
 11. The SGW of claim 7, the SGW is furtheroperative to receive a dynamically updated DTCI from the at least oneGTP entity.
 12. The SGW of claim 7, wherein the mobility management nodeis a Mobility Management Entity, a Serving General packet radio serviceSupport Node, SGSN, or a S4-SGSN.
 13. A method, in a core network nodefor dynamically managing a Packet Data Network, PDN, connection for awireless device, the core network node comprising a stored DelayTolerance Connection Indicator, DTCI, indicating if communications on anidentified PDN connection for the wireless device can be delayed, thecore network node being configured for a Network Triggered ServiceRestoration Procedure, method comprising: receiving, from a PolicyControl and Charging Rules Function, PCRF, or another core network node,an updated DTCI indicating a changed status with respect to if theidentified PDN connection for the wireless device is delay tolerant; andstoring the updated DTCI within the core network node.
 14. The method ofclaim 13, wherein the updated DTCI is received from the PCRF and thecore network node is a PDN Gateway, PGW, the method further comprisingforwarding, to a Serving Gateway, SGW, the updated DTCI.
 15. The methodof claim 13, wherein the updated DTCI is received from a PDN Gateway,PGW, and the core network node is Serving Gateway, SGW, the methodfurther comprising forwarding, to a mobility management node, theupdated DTCI.
 16. The method of claim 15, wherein the method furthercomprises managing the PDN connection, wherein the managing comprises:deleting the PDN connection if the DTCI indicates the PDN connection isdelay tolerant; or maintaining the PDN connection if the DTCI indicatesthe PDN connection is not delay tolerant.
 17. The method of claim 13,wherein the updated DTCI is received from a Serving Gateway, SGW, andthe core network node is a mobility management node.
 18. The method ofclaim 15, wherein the mobility management node is a Mobility ManagementEntity, a Serving General packet radio service Support Node, SGSN, or aS4-SGSN.
 19. A core network node for dynamically managing a Packet DataNetwork, PDN, connection for a wireless device, the core network nodecomprising a stored Delay Tolerance Connection Indicator, DTCI,indicating if communications on an identified PDN connection for thewireless device can be delayed, the core network node comprising aprocessor and a memory, said memory comprising instructions executableby said processor whereby said core network node is operative to:receive, from a Policy Control and Charging Rules Function, PCRF, oranother core network node, an updated DTCI indicating a changed statuswith respect to if the identified PDN connection for the wireless deviceis delay tolerant; and store the updated DTCI within the core networknode.
 20. The core network node of claim 19, wherein the updated DTCI isreceived from the PCRF and the core network node is a PDN Gateway, PGW,the core network node is further operative to forward, to a ServingGateway, SGW, the updated DTCI.
 21. The core network node of claim 19,wherein the updated DTCI is received from a PDN Gateway, PGW, and thecore network node is Serving Gateway, SGW, the core network node isfurther operative to forward, to a mobility management node, the updatedDTCI.
 22. The core network node of claim 21, wherein the management ofthe PDN connect further comprises the core network node being operativeto: delete the PDN connection if the DTCI indicates the PDN connectionis delay tolerant; or maintain the PDN connection if the DTCI indicatesthe PDN connection is not delay tolerant.
 23. The core network node ofclaim 19, wherein the updated DTCI is received from a Serving Gateway,SGW, and the core network node is a mobility management node.
 24. Thecore network node of claim 21, wherein the mobility management node is aMobility Management Entity, a Serving General packet radio serviceSupport Node, SGSN, or a S4-SGSN.
 25. A method, in a Policy Control andCharging Rules Function, PCRF, for dynamically managing a Packet DataNetwork, PDN, connection for a wireless device, the method comprising:detecting a status change in a delay tolerance of the PDN connection,wherein the status change presents a change with respect to if theidentified PDN connection for the wireless device is capable ofreceiving delayed communications; updating a Delay Tolerance ConnectionIndicator, DTCI, based on the detected status change; and sending, to aPDN Gateway, PGW, the updated DTCI.
 26. A Policy Control and ChargingRules Function, PCRF, for dynamically managing a Packet Data Network,PDN, connection for a wireless device, the PCRF comprising a processorand a memory, said memory comprising instructions executable by saidprocessor whereby said PCRF is operative to: detect a status change in adelay tolerance of the PDN connection, wherein the status changepresents a change with respect to if the identified PDN connection forthe wireless device is capable of receiving delayed communications;update a Delay Tolerance Connection Indicator, DTCI, based on thedetected status change; and send, to a PDN Gateway, PGW, the updatedDTCI.